Tube array type nitrogen canister

ABSTRACT

A tube-array-type liquid nitrogen container includes a container body having a mouth; a tube array component received in the container body; and a top cap sealing the mouth from above. The top cap is rotatable in the mouth. The tube array component is composed of a plurality of holding tubes. The holding tube is opened at one end thereof, wherein the opening thereof faces the top cap. The top cap has at least one tube access passing therethrough. Each tube access is atop covered by a tube access cover. The tube-array-type liquid nitrogen container uses a tube-array component composed of the a plurality of holding tubes to store the freezing tubes, and is cooperated with the rotatable top cap and an external robotic arm, thereby improving space utilization and thermal insulation, effectively ensuring safety of the freezing tubes, and facilitating automatic storage of freezing tubes.

This application is a Continuation of U.S. application Ser. No.16/687,139, filed Nov. 18, 2019, now U.S. Pat. No. 10,890,295, issued onJan. 12, 2021, which is a Continuation of U.S. application Ser. No.15/811,161, filed Nov. 13, 2017, now U.S. Pat. No. 10,514,130, issued onDec. 24, 2019, which claims priority to China Patent Application No.CN201611026500.8, filed Nov. 14, 2016. The entirety of theaforementioned applications is incorporated herein by reference.

FIELD

The present invention relates to a tube-array-type liquid nitrogencontainer.

DESCRIPTION OF RELATED ART

Liquid nitrogen containers are extensively used in hospitals andlaboratories, mainly for freezing and storing biological materials suchas cells and tissues. A traditional liquid nitrogen container typicallyis a double-layer vacuum container that is made by soldering. Such acontainer has eccentrically an opening and internally a rotatable innerrotator. The inner rotator carries a basket, in which freezing tubes areloaded. Since soldering of such a large device unavoidably has somedeformation, accurate rotation of the inner rotator is hard to achieve,in turn making automatic storage of freezing tubes impossible.

SUMMARY

For solving the problem of existing liquid nitrogen containers thatautomatic storage of freezing tubes is impossible, the present inventionprovides a tube-array-type liquid nitrogen container.

According to the present invention, a tube-array-type liquid nitrogencontainer comprises a container body that has a mouth; a tube arraycomponent that is received in the container body; and a top cap thatseals the mouth from above. The top cap is rotatable in the mouth. Thetube array component includes a plurality of holding tubes eachconfigured to hold a freezing tube. The holding tube is opened at oneend thereof, wherein the opening faces the top cap. The top cap has atleast one tub access passing therethrough, and each tube access is atopcovered by a tube access cover. The tube-array-type liquid nitrogencontainer uses a tube-array component composed of a plurality of holdingtubes to store freezing tubes, and with the cooperation of the top capand the external robotic arm, it realizes automatic access of freezingtubes.

Preferably, the container body has a double-layer structure with avacuum zone sandwiched between its two layers. Since the intermediatespace of the container body is applied with vacuum to form the vacuumzone that provides thermal insulation to the interior of the containerbody.

Preferably, the container body comprises an inner column and an outercolumn sleeved outside the inner column. The inner column and the outercolumn are fixed to each other at bottom. The inner column has its toplower than the top of the outer column. The inner column and the outercolumn have their tops connected through a corrugated pipe. Thecorrugated pipe has a wall thickness much smaller than the thickness ofthe inner column, and meanwhile the stroke is increased by more than onetime, so as to reduce heat transmitted to the bottom of the innercolumn, thereby reducing loss of the liquid nitrogen.

Further preferably, the container body further comprises a sleeve forthe corrugated pipe. The sleeve for the corrugated pipe comprises asleeve end fixed to the top of the outer column and a sleeve bodyextending downward from the sleeve end. The sleeve body is locatedinside the corrugated pipe. The sleeve body has its outer periphery thatfaces the corrugated pipe fitted with the inner periphery of thecorrugated pipe, and the sleeve body has its lower end portion fixed tothe inner column. The sleeve for the corrugated pipe prevents the innercolumn deformation caused by corrugated pipe being lengthened.

Further preferably, the inner periphery of the sleeve body is axiallysloped and is fitted with the top cap in a sealing manner. The sleevebody with the sloped inner periphery can fit with top cap in a sealingmanner better.

Preferably, tube array component further comprises an upper positioningplate, a lower positioning plate, and a central axle that fixedlyconnects the upper positioning plate and the lower positioning plate.The upper positioning plate is provided with a plurality of upperpositioning holes, and the lower positioning plate is provided with aplurality of lower positioning holes. Each of the upper positioningholes is coaxially aligned with one of the lower positioning holes. Theholding tube passes through the upper positioning hole and getspositioned in the corresponding lower positioning hole.

Preferably, an auxiliary ball is arranged at the bottom of the holdingtube, and the freezing tube is rested on the auxiliary ball. In additionto pushing the freezing tube during the tube-drawing operation, theauxiliary ball also provides damping function when the freezing tubemoves downward in the holding tube.

Preferably, the top cap is provided with at least one position sensor.The position sensors may be arranged in circumferential direction of thetop cap. The position sensors detect the rotation angle of the top cap,so as to ensure that the top cap rotates accurately.

Preferably, the tube access covers the entire area in radial directionof the tube array component. No matter where the access site of thefreezing tube is in the tube array component, the tube access can bealigned to the tube access site by simply rotating the top cap for acertain angle.

Preferably, the tube access cover comprises a roof for the tube accesscover and a insulating layer for the tube access cover, wherein theinsulating layer is located below the roof, and the insulating layer isfitted with the tube access in a sealing manner. With the insulatinglayer for the tube access cover and the tube access fitting with eachother in a sealing manner, good thermal insulation can be achieved atthe tube access.

Based on the common sense in this art, the preferred terms can becombined in various ways to present various embodiments of the presentinvention.

The present invention provides the following positive advancements:

The tube-array-type liquid nitrogen container uses a tube-arraycomponent composed of a plurality of holding tubes to store the freezingtubes, and is cooperated with the rotatable top cap and an externalrobotic arm, thereby improving space utilization and thermal insulation,effectively ensuring safety of the freezing tubes, and facilitatingautomatic storage of freezing tubes.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an exploded view of a tube-array-type liquid nitrogencontainer of the present invention.

FIG. 2 is a structural drawing of the container body of thetube-array-type liquid nitrogen container of FIG. 1.

FIG. 3 is a partial enlarged view of the container body of FIG. 2.

FIG. 4 is a structural schematic drawing of the tube-array component ofthe tube-array-type liquid nitrogen container of FIG. 1.

FIG. 5 is a partial enlarged view of the tube-array component of FIG. 4.

REFERENCE NUMBERS

1 container body

11 mouth

12 outer column

13 inner column

14 corrugated pipe

15 sleeve for corrugated pipe

151 sleeve end

152 sleeve body

2 tube array component

21 holding tube

22 upper positioning plate

23 lower positioning plate

24 central axle

25 auxiliary ball

3 top cap

31 tube access

32 tube access cover

321 roof for the tube access cover

322 insulating layer for the tube access cover

33 top cap roof

34 top cap insulating layer

35 position sensor

4 freezing tube

DETAILED DESCRIPTION

The following preferred embodiments are made to clearly exhibit theabove-mentioned and other technical contents, features and effects ofthe present invention. However, they are not intended to limit thepresent invention in any way.

As shown in FIG. 1 to FIG. 5, the present invention provides atube-array-type liquid nitrogen container. It comprises a container body1 that has a mouth 11; a tube array component 2 that is received in thecontainer body 1; and a top cap 3 that seals the mouth 11 from above.The top cap 3 is rotatable in the mouth 11. The tube array component 2comprises a plurality of holding tubes 21 each configured to hold afreezing tube 4. The holding tube 21 is opened at one end thereof,wherein the opening of the holding tube 21 faces the top cap 3. The topcap 3 has at least one tube access 31, which tube access passes throughthe top cap 3. On the top, the tube access 31 is covered by a tubeaccess cover 32.

The tube-array-type liquid nitrogen container is configured to work withan external robotic arm for automatic access of the freezing tubesthrough the following process.

To extract a freezing tube 4 (also called freezing storage tube), theexternal robotic arm rotates the top cap 3 first such that the tubeaccess 31 of the top cap 3 is moved to a targeted site (i.e. a placeabove the holding tube 21 that holds the targeted freezing tube 4), andthen lifts the tube access cover 32 to open the tube access 31. At last,the robotic arm activates and moves its tube-drawing head toward thetube array component 2 from above, so as to form an upward drawing forcein the holding tube 21 that holds the targeted freezing tube 4, and drawthe freezing tube 4 from above until the freezing tube 4 enters thetube-drawing head.

To store a freezing tube, the external robotic arm first rotates the topcap 3 such that the tube access 31 of the top cap 3 is moved to atargeted site (i.e. a place above the holding tube 21 that is going toreceive the freezing tube 4), and then lifts the tube access cover 32 toopen the tube access 31. At last, the robotic arm places the freezingtube 4 to be stored into the holding tube 21.

The tube-array-type liquid nitrogen container uses a tube-arraycomponent 2 composed of a plurality of holding tubes 21 to storefreezing tubes 4, and with the cooperation of the top cap 3 and theexternal robotic arm, it realizes automatic access of freezing tubes 4.

As shown in FIG. 2 and FIG. 3, the container body 1 has a double-layerstructure with a vacuum zone sandwiched between its two layers. Theintermediate space of the container body 1 is applied with vacuum toform a vacuum zone, which provides thermal insulation to the interior ofthe container body 1.

In one embodiment, the container body 1 has the following configuration.The container body 1 comprises an outer column 12 and an inner column13, which is enclosed by the outer column 12 at outside. The innercolumn 13 and the outer column 12 are fixed to each other at bottom. Theinner column 13 has its top lower than the top of the outer column 1.The inner column 13 and the outer column 12 have their tops connectedthrough a corrugated pipe 14. The corrugated pipe 14 has a wallthickness much smaller than the thickness of the inner column 13, andmeanwhile the pathway is increased by more than one time, so as toreduce heat transmitted to the bottom of the inner column 13, therebyreducing loss of the liquid nitrogen.

The vacuum zone applies a downward pressure to the inner column 13. Forpreventing the deformation of the inner column 13 caused by corrugatedpipe 14 from being lengthened, a sleeve 15 for the corrugated pipeprecisely fitting the corrugation profile of the corrugated pipe 14 issleeved on the corrugated pipe 14. The sleeve 15 for the corrugated pipeis made of a non-metal material that has low thermal conductivity.

The sleeve 15 for the corrugated pipe is configured as below.

The sleeve 15 for the corrugated pipe comprises a sleeve end 151 fixedto the top of the outer column 12 and a sleeve body 152 extendingdownward from the sleeve end 151. The sleeve body 152 is located insidethe corrugated pipe 14. The outer periphery of the sleeve body 152 thatfaces the corrugated pipe 14, is fitted with the inner periphery of thecorrugated pipe 14. The sleeve body 152 has its lower end portion fixedto the inner column 13.

The inner periphery of the sleeve body 152 is such axially sloped thatthe inner periphery of the sleeve body 152 and the top cap 3 are fittedwith each other in a sealing manner. Therein, the top cap 3 comprises atop cap roof 33 and a top cap insulating layer 34 located below the topcap roof 33. The inner periphery of the sleeve body 152 and the outerperiphery of the top cap insulating layer 34 are fitted with each otherin a sealing manner.

As shown in FIG. 4 and FIG. 5, the tube array component 2 furthercomprises an upper positioning plate 22, a lower positioning plate 23,and a central axle 24 that fastens the upper positioning plate 22 andthe lower positioning plate 23. The upper positioning plate 22 isprovided with a plurality of upper positioning holes, and the lowerpositioning plate 23 is provided with a plurality of lower positioningholes. Each of the upper positioning holes is coaxially aligned with oneof the lower positioning holes. The holding tube 21 passes through theupper positioning hole and then gets fixed in the corresponding lowerpositioning hole. The upper positioning plate 22 and the lowerpositioning plate 23 are parallel to each other. The upper positioningplate 22 and the lower positioning plate 23 are centrally connected bythe central axle 24. The plural upper positioning holes are distributedalong the periphery of the central axle 24 in loop by loop manner, whilethe plural lower positioning holes are also distributed along theperiphery of the central axle 24 in loop by loop manner. An auxiliaryball 25 is arranged at the bottom of the holding tube 21, so that thefreezing tube 4 can be rested on the auxiliary ball 25. The auxiliaryball 25 has a diameter slightly smaller than that of the holding tube21, and is made of a relatively soft and lightweight material, such assilicone. When the tube-drawing head of the robotic arm draws thefreezing tube 4 upward, the auxiliary ball 25 will be also sucked andmoved upward, thereby pushing the freezing tube 4 above it to moveupward. In addition to pushing the freezing tube 4 during thetube-drawing operation, the auxiliary ball 25 also functions for dampingthe freezing tube 4 when the freezing tube 4 falls down into the holdingtube 21.

The top cap 3 is provided with at least one position sensor 35. Theposition sensors 35 may be arranged in circumferential direction of thetop cap 3. Before the accessing operation, a position of a freezing tube4 to be accessed is first detected. Then the robotic arm rotates andmoves the top cap 3 to a predetermined site. During rotation, theposition sensor 35 detects the rotation angle of the top cap 3, so as toensure that the top cap 3 rotates into a proper position. In anembodiment where plural position sensors 35 are arranged incircumferential direction of the top cap 3, wherein preferred that thetop cap 3 is peripherally provided with six evenly distributed positionsensors 35.

The tube access 31 covers the entire area in radial direction of thetube array component 2. No matter where the access site of the freezingtube 4 is in the tube array component 2, the tube access 31 can bealigned to the access site by simply rotating the top cap 3 for acertain angle, thereby realizing full coverage to all the access sitesin the tube array component 2. For minimizing the area of the tubeaccess 31 while providing full coverage, there may be a plurality oftube accesses 31 arranged at different positions in radial direction ofthe tube array component 2. Preferably, as shown in FIG. 1, there aretwo tube accesses 31. The minimized area of the tube access 31 helps tominimize loss of liquid nitrogen when the tube access 31 is open.

As shown in FIG. 1, the tube access cover 32 comprises a roof.321 forthe tube access cover and a insulating layer 322 for the tube accesscover, which insulating layer is located below the roof 321. Theinsulating layer 322 and the tube access 31 are fitted with each otherin a sealing manner.

The holding tube 21 is usually an aluminum tube, and has a length suchdesigned that the holding tube 21 is several times as long as the lengthof the freezing tube 4, so that a plurality of freezing tubes 4 can beput into the holding tube 21 successively. [64] To sum up, thetube-array-type liquid nitrogen container of the present invention usesthe tube-array component composed of a plurality of holding tubes tostore the freezing tubes, and is cooperated with the rotatable top capand an external robotic arm, thereby improving space utilization andthermal insulation, effectively ensuring safety of the freezing tubes,and facilitating automatic storage of freezing tubes.

The present invention has been described with reference to the preferredembodiments and it is understood that the embodiments are not intendedto limit the scope of the present invention. Moreover, as the contentsdisclosed herein should be readily understood and can be implemented bya person skilled in the art, all equivalent changes or modificationswhich do not depart from the concept of the present invention should beencompassed by the appended claims.

What is claimed is:
 1. A tube-array-type liquid nitrogen container,comprising: a container body with a mouth; a top cap sealing the mouthfrom above, wherein the top cap is rotatably arranged in the mouth,wherein the tube array component includes a plurality of holding tubes,each holding tube has a top end and bottom end, and each holding tube isconfigured to hold a freezing tube, the holding tubes are opened at oneend thereof that openings of the holding tubes face the top cap, whereinthe top cap has at least one tube access passing through the top cap,and the at least one tube access is covered by a tube access cover onthe top end, and wherein the container body comprises an inner columnand an outer column sleeving the inner column at an outside, wherein theinner column and the outer column are fixed to each other, the innercolumn has a top lower than a top of the outer column, and the top ofthe inner column and the top of the outer column are connected.
 2. Thetube-array-type liquid nitrogen container of claim 1, wherein thecontainer body has a double-layer structure with a vacuum zonesandwiched between its two layers.
 3. The tube-array-type liquidnitrogen container of claim 1, wherein the tube array component furthercomprises an upper positioning plate, a lower positioning plate, and acentral axle fixedly connecting the upper positioning plate and lowerpositioning plate, wherein the upper positioning plate is provided witha plurality of upper positioning holes, the lower positioning plate isprovided with a plurality of lower positioning holes, and each of theplurality of upper positioning holes is coaxially aligned with one ofthe plurality of lower positioning holes, so that the holding tubepassing through each of the plurality of upper positioning holes can bepositioned in its corresponding lower positioning hole.
 4. Thetube-array-type liquid nitrogen container of claim 3, wherein anauxiliary ball is arranged at a bottom of the holding tube, and thefreezing tube is rested on the auxiliary ball.
 5. The tube-array-typeliquid nitrogen container of claim 1, wherein the tube access covers anentire area in radial direction of the tube array component.
 6. Thetube-array-type liquid nitrogen container of claim 1, wherein the tubeaccess cover comprises a roof for the tube access cover and aninsulating layer for the tube access cover, wherein the insulating layeris located below the roof, and the insulating layer is fitted with thetube access in a sealing manner.
 7. The tube-array-type liquid nitrogencontainer of claim 1, wherein the top of the inner column and the top ofthe outer column are connected through a corrugated pipe.
 8. Thetube-array-type liquid nitrogen container of claim 7, further comprisinga sleeve for the corrugated pipe, wherein the sleeve comprises a sleeveend fixed to the top of the outer column, a sleeve body located insidethe corrugated pipe, wherein the sleeve body comprises a lower endportion fixed to the inner column.
 9. The tube-array-type liquidnitrogen container of claim 8, wherein the sleeve body has an outerperiphery that faces an inner periphery of the corrugated pipe.
 10. Thetube-array-type liquid nitrogen container of claim 9, wherein the sleevebody comprises an inner periphery that is axially sloped and fitted withthe top cap in a sealing manner.